liang zou | Microgrid system | Best Academic Researcher Award

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Mr. liang zou | Microgrid system | Best Academic Researcher Award

professor, Shandong University, China

Professor Zou Liang is a leading scholar in the field of electrical engineering, currently serving as the Director of the Institute of Electrical Theory and New Technology at the School of Electrical Engineering, Shandong University. He holds the titles of professor and doctoral supervisor and has made significant contributions to high voltage and insulation technology. He has been recognized through numerous national and provincial honors, including selection for China’s National Youth Talent Program, designation as a leading talent in innovation and entrepreneurship in Jiangsu Province, and acknowledgment as an outstanding young and middle-aged scholar at Shandong University. He holds key professional roles such as committee member of the China Electrotechnical Society’s Energy Storage Systems and Electromagnetic Compatibility Committees, expert contributor to the “Light of Electric Power” initiative, and serves as director of the Shandong Electrotechnical Society. As an IEEE member and frequent reviewer for prestigious journals, Professor Zou has established a distinguished academic presence nationally and internationally.

Professional Profile

ORCID

🎓 Education

Professor Zou Liang received a comprehensive education in electrical engineering, culminating in a doctoral degree that laid the foundation for his specialized focus in high voltage engineering and new insulation technologies. His academic training emphasized both theoretical and applied research, which he has continuously advanced throughout his career. As an educator, he teaches undergraduate courses such as Fundamentals of Electrical Engineering (High Voltage Section) and Power System Grounding Technology, and a graduate-level course on Online Monitoring and Fault Diagnosis of Electrical Equipment, demonstrating his strong integration of teaching and research.

💼 Experience

From March 2021 to March 2023, Professor Zou served as the Director of the Mobile Program for Electrical Science and Engineering under the National Natural Science Foundation of China. His leadership experience extends to national-level research programs, where he has successfully managed complex, multidisciplinary projects. With over a decade of involvement in electrical engineering innovation, he has coordinated major government and industry-funded projects, collaborated across institutions, and provided technical consulting for the development of cutting-edge power system technologies.

🔬 Research Interests

Professor Zou’s research centers on the high-frequency discharge and electromagnetic optimization of new energy equipment, as well as the regulation and modification of high-performance insulation materials. His work bridges theoretical modeling and practical applications, including micromagnetic simulations, plasma degradation methods, and molecular dynamics studies of advanced composite materials. A pioneer in the field, he is particularly noted for advancing knowledge in nanocrystalline soft magnetic materials and for developing interdisciplinary methodologies that combine physics, materials science, and power systems engineering.

📚 Publications Top Notes

Micromagnetic Simulation of Saturation Magnetization of Nanocrystalline Soft Magnetic Alloys under High-Frequency Excitation

Authors: K. Guo, L. Zou*, L. Dai, et al.
Published in: Symmetry, Volume 14, Issue 7, Article 1443, Year: 2022
DOI: [Available upon request]
Summary:
This paper presents a micromagnetic simulation approach to analyze the saturation magnetization behavior of nanocrystalline soft magnetic alloys when exposed to high-frequency excitation fields.

Molecular Dynamics Simulation of the Influence of Functionalized Doping on Thermodynamic Properties of Cross-Linked Epoxy/Carbon Nanotube Composites

Authors: M. Ding, L. Zou*, L. Zhang, T. Zhao, Q. Li
Published in: Transactions of China Electrotechnical Society, Volume 36, Issue 23, Pages 5046–5057, Year: 2021
Summary:
This research employs molecular dynamics (MD) simulations to evaluate the thermodynamic properties of epoxy/carbon nanotube (CNT) composites subjected to various functionalized doping techniques.

A Review on Factors That Affect Surface Charge Accumulation and Charge-Induced Surface Flashover

Authors: M. Yuan, L. Zou*, Z. Li, L. Pang, T. Zhao, L. Zhang, J. Zhou, P. Xiao, S. Akram, Z. Wang, S. He
Published in: Nanotechnology, Volume 32, Issue 26, Year: 2021
Summary:
This comprehensive review article explores the various physical, chemical, and environmental factors that influence surface charge accumulation and the onset of flashover in insulating materials. The authors categorize the influence of surface morphology, humidity, material defects, electric field distribution, and charge mobility.

Investigation of Non-Thermal Atmospheric Plasma for the Degradation of Avermectin Solution

Authors: Y. Lv, L. Zou*, H. Li, Z. Chen, X. Wang, Y. Sun, L. Fang, T. Zhao, Y. Zhang
Published in: Plasma Science and Technology, Volume 23, Issue 5, Year: 2021
Summary:
This study examines the degradation efficiency of non-thermal atmospheric plasma (NTAP) on avermectin, a commonly used pesticide, in aqueous solutions. The paper analyzes plasma-induced chemical reactions, energy transfer mechanisms, and byproduct formation.

Influence of the External and Internal Factors on Saturation Magnetization Process for Nanocrystalline Alloy

Authors: Liang Zou, Jiale Wu, Zhiyun Han, et al.
Published in: IEEE Transactions on Magnetics, Volume 54, Issue 10, Article 7205708, Year: 2018
Summary:
This paper investigates how both intrinsic factors (such as atomic structure and grain size) and extrinsic conditions (such as applied magnetic field and temperature) affect the saturation magnetization of nanocrystalline magnetic alloys.

🔚 Conclusion

Professor Zou Liang’s academic and research excellence, coupled with his visionary leadership in engineering innovation, marks him as a distinguished contributor to the field of electrical engineering. His work not only addresses critical scientific challenges in high voltage and insulation technology but also offers practical solutions that advance energy system reliability and environmental safety. Through rigorous scholarship, prolific publication, and dedicated service to professional societies, he continues to set a standard for excellence in science, technology, and education.

Nashwa Yousif | Renewable Energy | Women Researcher Award

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Assist. Prof. Dr. Nashwa Yousif | Renewable Energy | Women Researcher Award

Assist. Prof. Dr. Nashwa Yousif, Egyptian Atomic Energy Authority, Egypt

Dr. Nashwa Mohamed Mahmoud Yousif is an Assistant Professor of Material Sciences at the Egyptian Atomic Energy Authority, specializing in energy storage and renewable energy research. With over 18 years of academic and research experience, she has contributed extensively to advanced electrochemical analysis, nanomaterials development, and polymer/metal oxide composites for sustainable energy applications. Currently based at the Electrochemical Lab of the Solid State and Accelerators Department at the National Center for Radiation Research & Technology (NCRRT), her contributions span academic supervision, collaborative research, and high-impact journal publications.

Professional Profile

ORCID

🎓 Education

Dr. Yousif’s academic journey is rooted in physics and material science. She steadily progressed through academic ranks, beginning as a physics researcher in 2007. Her advanced studies led her to specialize in solid-state physics and energy materials, which has underpinned her extensive work on electrochemical energy storage systems and nanocomposites.

🧪 Experience

Dr. Yousif has steadily grown her academic career within the Egyptian Atomic Energy Authority. She began as a physics researcher (2007–2012), before being promoted to assistant lecturer (2012–2016), and lecturer (2016–2022). In 2022, she assumed the role of Assistant Professor in Material Sciences at the NCRRT. Throughout this time, she has been deeply involved in both laboratory research and the mentorship of graduate students, significantly influencing Egypt’s scientific landscape in the fields of renewable energy and electrochemical materials.

🔬 Research Interests

Her core research interests include the development of cathode materials for multivalent ion batteries, synthesis of polymer/metal oxide nanocomposites, and conversion of plastic waste into carbon nanomaterials for energy storage. She focuses on scalable, eco-friendly approaches to sustainable energy solutions, particularly in enhancing battery technology and supercapacitor performance.

📚 Publications Top Notes

🔬 Title: Facile Synthesis and Characterization of Perovskite-Type Nd₁−ₓCaₓMnO₃ Nanocomposites for High-Performance Supercapacitor Electrodes

📅 Published: May 2025
📘 Journal: Journal of Electronic Materials
👥 Contributors: Soraya Abdelhaleem, M. S. Shalaby, H. M. Hashem, Nashwa M. Yousif

Summary:
This research explores the synthesis of Nd₁−ₓCaₓMnO₃ perovskite-type nanocomposites using a facile route and their application as electrode materials in supercapacitors. The study reveals how calcium doping impacts the crystal structure and electrochemical behavior, resulting in enhanced specific capacitance and charge-discharge performance. The nanocomposites exhibit excellent electrochemical stability, making them promising candidates for next-generation energy storage devices.

🔬 Title: Plastic Waste‐Derived Carbon Nanotubes Decorated with Mo₂C, MoO₃, or MoO₃/Mo₂C as Effective Nanocomposite Materials for Supercapacitor Applications

📅 Published: May 2025
📘 Journal: ChemistrySelect
👥 Contributors: Ahmed E. Awadallah, Ateyya A. Aboul‐Enein, Nashwa M. Yousif, Mostafa A. Azab, Ahmed M. Haggar

Summary:
This environmentally focused study converts plastic waste into carbon nanotubes (CNTs) and further functionalizes them with Mo₂C, MoO₃, and a hybrid MoO₃/Mo₂C composite. The resulting materials exhibit exceptional electrochemical properties, including high conductivity and capacitance. The work provides a dual solution for plastic waste management and supercapacitor enhancement, highlighting the potential of green nanotechnology.

🔬 Title: Impact of Carbon Nanotubes on Superconducting Properties and Ferromagnetism of Indium-Doped Bi-2212 Superconductors: Critical Current Density Enhancement

📅 Published: January 2025
📘 Journal: Physica B: Condensed Matter
👥 Contributors: Soraya Abdelhaleem, Manale Noun, Nashwa M. Yousif, Mustafa Saeed Shalaby

Summary:
This article examines how the inclusion of carbon nanotubes influences the superconducting behavior of indium-doped Bi-2212 ceramics. The findings indicate enhanced critical current density and a marked effect on the magnetic and ferromagnetic properties. The research provides insight into the interplay between nanostructures and superconducting materials, opening avenues for high-efficiency superconductors in electronics.

🔬 Title: Electrochemical Performance of Flexible Supercapacitor Electrodes Based on EVA/PANI@CNT Nano-Composite

📅 Published: December 2024
📘 Journal: Russian Journal of Electrochemistry
👥 Contributors: Nashwa M. Yousif, Mohamed R. Balboul

Summary:
This study introduces a novel flexible electrode made from a composite of ethylene-vinyl acetate (EVA), polyaniline (PANI), and carbon nanotubes (CNTs). The material displays impressive capacitance retention and flexibility, ideal for wearable energy storage devices. It marks a significant advancement in flexible supercapacitor technology through a cost-effective and scalable approach.

🔬 Title: γ‐Irradiation Hardness Investigations of (PANI)₁−ₓ(Bi₂Te₃)ₓ Composites for Thermistor Applications

📅 Published: February 10, 2023
📘 Journal: Journal of Applied Polymer Science
👥 Contributors: Mustafa Saeed Shalaby, Soraya Abdelhaleem, Eman O. Taha, Nashwa M. Yousif

Summary:
The paper investigates the impact of γ-irradiation on polyaniline/Bi₂Te₃ composites, assessing their structural stability and electrical response. The results demonstrate that controlled irradiation improves the thermistor behavior of the composite, making it suitable for temperature-sensing applications in radiation-exposed environments. This work contributes to the design of robust, radiation-resistant sensors.

🧭 Conclusion

Dr. Nashwa M. Yousif exemplifies the modern researcher’s commitment to both innovation and sustainability. Her work bridges academic research and practical solutions, tackling some of the world’s most urgent energy challenges. Through her publications, graduate supervision, and national projects, she continues to lead with scientific integrity and a forward-looking vision. Her contributions make her a strong contender for recognition in national and international award platforms, especially in categories honoring women in science and sustainability innovation.